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Mammary Epithelial Cells Cultured onto Non-Woven Nanofiber Electrospun Silk-Based Biomaterials to Engineer Breast Tissue ModelsMaghdouri-White, Yas 09 April 2014 (has links)
Breast cancer is one of the most common types of cancer affecting women in the world today. To better understand breast cancer initiation and progression modeling biological tissue under physiological conditions is essential. Indeed, breast cancer involves complex interactions between mammary epithelial cells and the stroma, both extracellular matrix (ECM) and cells including adipocytes (fat tissue) and fibroblasts (connective tissue). Therefore, the engineering of in vitro three-dimensional (3D) systems of breast tissues allows a deeper understanding of the complex cell-cell and cell-ECM interactions involved during breast tissue development and cancer initiation and progression. Furthermore, such 3D systems may provide a viable alternative to investigate new drug or drug regimen and to model and monitor concurrent cellular processes during tumor growth and invasion. The development of suitable 3D in vitro models relies on the ability to mimic the microenvironment, the structure, and the functions of the breast tissue. Different approaches to develop a novel 3D breast model have been investigated. Most models use gel scaffolds, including Matrigel® and collagen to generate breast tissue-like structures. However, the physicochemical, mechanical, and geometrical properties of these scaffolds only partially meet the mechanical, physical, and chemical parameters of the breast tissue matrix. In the present studies, we investigated the overall hypothesis that electrospun SF-derived scaffolds promote mammary cell growth and the formation of mammary-like structures depending on the composition and/or coating of the scaffolds with ECM proteins. Through an extensive literature search (1) the importance of 3D modeling of tissues and organs in vivo, (2) 3D modeling of the mammary tissue and currently available models, (3) the properties and applications of SF in tissue modeling and regeneration were reviewed (Chapter 1). Our studies provide evidence of the effects of various concentrations (Chapter 2) of SF along with different electrospinning techniques (Chapter 3) on the structure of electrospun scaffolds and whether those scaffolds provide suitable microenvironments for mammary epithelial cells as determined by MCF10A cell attachment, viability, and structure formation. Further, we investigated the effects of the key ECM proteins collagen I (Chapter 4) and laminin (Chapter 5) used to blend or coat, respectively, SF scaffolds on the attachment, viability and structure formation of mammary epithelial cells. Our studies first highlight the mechanical and physical properties of the different SF-derived scaffolds through various SF concentrations and electrospinning techniques. Second, the biocompatibility of these SF electrospun scaffolds was defined based on MCF10A cell survival and adhesion. Third, our data indicate that scaffolds derived from blended and/or coated SF with collagen I also promoted human mammary cell survival and adhesion. Lastly, our observations suggest that on laminin-coated SF scaffolds MCF10A mammary cells, in the presence of lactogenic hormones, differentiated forming acinus-like structures. Overall, these studies provide evidence that SF electrospun scaffolds closely mimic the structure of the ECM fibers and allow many advantages such as; physical and chemical modification of the microenvironment by varying electrospinning parameters and addition of various proteins, hormones, and growth factors, respectively. Further, coating these SF scaffolds with essential ECM proteins, in particular laminin, promote cell-ECM interactions necessary for cell differentiation and formation of growth-arrested structures, through providing cell integrin binding sites and appropriate chemical cues.
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Conception et élaboration d'échafaudages de nanofibres à dégradation contrôlée pour des applications en médecine régénératrice vasculaire / Design and elaboration of degradation-controlled nanofiber scaffold for vascular regenerative medicine applicationSabbatier, Gad 30 June 2015 (has links)
L’absence de croissance en monocouche des cellules endothéliales sur la paroi des prothèses vasculaires est une des causes d’échec de leur implantation chez l’humain. Des études précédentes ont montré que le recouvrement de ces prothèses par un échafaudage de nanofibres d’acide polylactique (PLA), fabriqué par un système de filage par jet d’air innovant, peut être utilisé pour promouvoir la croissance des cellules endothéliales de façon adéquate. Ainsi, le caractère dégradable d’un matériau comme le PLA permettrait son remplacement graduel par la matrice extra-cellulaire produite par les cellules. D’autre part, la réussite d’une transition entre les nanofibres dégradables et la matrice extra-cellulaire nécessite un remplacement contrôlé et approprié. Or, la dégradation des nanofibres de PLA, dépendant de ses séquences stéréochimiques, est généralement trop longue et peut induire une cytotoxicité relative pendant sa dégradation. Dans ce contexte, les études de cette thèse ont pour objectifs de mieux comprendre la formation des fibres lors du filage, d’optimiser la fabrication des échafaudages permettant ainsi la création de nanofibres d’autres polymères, puis, de concevoir des nanofibres provenant d’un polymère mieux adapté à nos besoins, d’évaluer leur mécanisme de dégradation et sa cytotoxicité durant sa dégradation. Les travaux d’optimisation du système de filage ont démontré que la concentration avec un effet prépondérant. Ainsi, la mesure de la viscosité permet de trouver les paramètres adéquats pour le filage de polymère. Ensuite, un poly(L-lactide) semi-cristallin (PLLA) et un terpolymère de poly(lactide-co-ε-caprolactone) (PLCL) dédié pour des applications vasculaires ont été synthétisés et filés par jet d’air. Ces échantillons ont été dégradés en solution aqueuse et caractérisés par des méthodes physico-chimiques afin de mieux comprendre leurs mécanismes de dégradation et mis en présence de cellules endothéliales pour évaluer leur cytotoxicité. La comparaison entre les échafaudages des deux polymères a montré des comportements singuliers en dégradation, dépendants des caractéristiques thermiques des polymères. De plus, ces mécanismes de dégradation des nanofibres ont une influence directe sur la sensibilité des cellules endothéliales face aux produits de dégradation. En conclusion, ces travaux de doctorat présentent une solution prometteuse pour améliorer les prothèses vasculaires et qui pourrait être appliquée pour résoudre plusieurs problématiques en médecine régénératrice. / The absence of neo-endothelium on the intimal surface of vascular substitutes is known to be one cause of failure upon implantation of these prostheses in humans. Previous studies have shown that the coating of these substitutes with a nanofiber scaffold, made with an innovative air spinning device, can be used to promote a suitable endothelial cells growth. On one hand, the degradable feature of material as PLA enable the progressive replacement of the scaffold by the extracellular matrix of cells. On the other hand, the success of this replacement between degradable nanofibers and the extracellular matrix requires to be appropriate and controlled. Yet, the PLA nanofiber degradation process, which depends on its stereosequences, is generally too long for this application and could involve cell sensitivity during the degradation. In this context, studies from this thesis aim to understand the fibers formation during spinning, optimizing the scaffold fabrication as well as to promote the making of novel polymer scaffolds, then, design solution to polymeric nanofiber scaffolds for vascular application, evaluate its degradation mechanism and cytotoxicity during degradation process. The work on spinning device optimisation has demonstrated that the concentration had a dominant effect. Thus, viscosity measurements enable to find suitable parameters for polymer spinning. Then, a semi-cristalline poly(L-lactide) (PLLA) and a poly(lactide-co-ε-caprolactone) (PLCL) terpolymer specifically made for vascular application have been synthesized and air-spun. These samples were degraded in aqueous solution and characterized by physical and chemical methods to better understand their degradation mechanisms and seeded with endothelial cells to evaluate their cytotoxicity. The comparison between the two polymers scaffolds have shown surprising degradation behaviors depending on thermal properties of polymers. Moreover, these nanofiber degradation mechanisms have a direct influence on endothelial cells sensitivity with degradation by-products. To conclude, these works of doctorate display a promising solution to improve vascular prostheses and which could be applied to solve several issues in regenerative medicine field.
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Hidrólise de polpa de sisal como via de produção de etanol e materiais / Sisal pulp hydrolysis for the production of ethanol and materialsLacerda, Talita Martins 25 April 2012 (has links)
A possível escassez dos recursos fósseis, juntamente com o aumento imprevisível dos respectivos preços, levou, nas últimas décadas, a um aumento considerável de iniciativas dedicadas não só à procura de fontes alternativas de produtos químicos e polímeros a partir de fontes renováveis, mas também de fontes alternativas de energia - em particular a biomassa vegetal. O estudo desenvolvido no presente trabalho está inserido neste contexto. A despolimerização de celulose de sisal pode ocorrer via hidrólise, ácida ou enzimática, podendo resultar nos açúcares fermentescíveis necessários para a produção do chamado etanol celulósico e, em etapas intermediárias do processo, em micro e nanopartículas, que podem atuar como reforço de matriz polimérica baseada, por exemplo, em quitosana. O estudo aqui relatado está relacionado à análise do material celulósico não reagido durante a hidrólise, e do licor que contém principalmente glicose. As reações de hidrólise ácida e enzimática de polpa de sisal (constituída de celulose e hemicelulose) foram exploradas. Uma importante característica que envolve a hidrólise ácida de biomassa é a possibilidade de utilização de diversos ácidos, pois a princípio, necessita-se apenas de uma fonte de prótons no meio aquoso para que a reação ocorra. Neste contexto, em uma primeira etapa, uma série de reações de hidrólise ácida de polpa de sisal, previamente tratada com solução alcalina (mercerizada) ou não, foi feita com ácido sulfúrico (0,9 - 4,6 molL-1, 100°C, 6h de reação). Em uma segunda etapa, o ácido sulfúrico foi substituído por ácido oxálico, e os tempos de reação foram maiores (18h) que aqueles considerados para o ácido sulfúrico, tendo em vista o menor valor do pKa do ácido oxálico. Reações de hidrólise enzimática foram realizadas com o uso de um complexo enzimático comercial (Accellerase 1500 - Genencor), e dois diferentes pré-tratamentos, ambos visando à eliminação de hemiceluloses, foram avaliados, sendo: mercerização e tratamento com solução de ácido oxálico 0,9 molL-1. Para acompanhar os processos, em determinados intervalos de tempo, foram retiradas alíquotas do meio reacional, sendo que os licores foram analisados por cromatografia líquida de alta eficiência (CLAE), a fim de avaliar a natureza e o teor dos produtos da hidrólise. As polpas residuais (não hidrolisadas), suspensas no licor, foram avaliadas por microscopia eletrônica de varredura, massa molar média por viscosimetria capilar, índice de cristalinidade por difração de raios X e tamanhos médios das fibras a partir de um analisador de fibras (MorFi - analisador de tamanho médio de fibras por imagem), e espalhamento de luz (FOQELS). Para todas as reações de hidrólise ácida estudadas, as massas molares médias das polpas residuais diminuíram até dez vezes logo nos primeiros minutos de reação e os valores de índice de cristalinidade mostraram que as regiões não cristalinas da celulose são primeiramente hidrolisadas, sendo as regiões cristalinas uma grande barreira frente à hidrólise. Os resultados mostraram que o aumento da concentração do catalisador ácido elevou consideravelmente a porcentagem de hidrólise, principalmente no caso do ácido oxálico que, quando usado na concentração de 0,9 molL-1, não foi capaz de hidrolisar com eficiência as cadeias de celulose, mas apenas eliminou as hemiceluloses presentes na polpa, motivo que levou à sua aplicação como agente de pré-tratamento para a polpa frente à hidrólise enzimática. Os rendimentos das reações mostraram que o ácido sulfúrico chega a ser aproximadamente 25% mais eficiente que o ácido oxálico em termos de produção de glicose. Entretanto, o ácido oxálico possui a grande vantagem de ser proveniente de fontes renováveis e, se usado nas concentrações adequadas, pode ser uma excelente opção como pré-tratamento da polpa de celulose para as reações de hidrólise. Os resultados de hidrólise enzimática mostraram que a polpa que passou pelo pré-tratamento da mercerização foi mais eficiente como material de partida do que aquela tratada com ácido oxálico, já que a primeira levou a concentrações de glicose até 2,5 vezes maiores, nas mesmas condições de concentração de enzima, temperatura e tempo de reação. As reações de hidrólise ácida e enzimática de material lignocelulósico são de grande importância no que diz respeito à produção de etanol de segunda geração e micro/nanofibras que podem ser incorporadas em materiais. Filmes de matriz de quitosana foram produzidos com a inserção de fibras de celulose sem tratamento, mercerizada, e residuais das reações de hidrólise ácida e enzimática, em diferentes concentrações (2,5, 7,5 e 15% em massa). Os filmes foram submetidos à solicitação de tração, e a morfologia foi acessada por microscopia eletrônica de varredura de emissão de campo (FEG-MEV). Os resultados mostraram que, no geral, o filme de quitosana (69 MPa), assim como os baseados em quitosana/celulose (75 MPa), apresentam resistência à tração superior ou no mesmo patamar de filmes similares descritos na literatura. Este trabalho forneceu resultados promissores e está largamente inserido no interesse atual de utilização de materiais provenientes de fontes renováveis preferencialmente àqueles de fontes fósseis. / The possible shortage of crude oil and the unpredictable increase in its prices have led to an impressive expansion of initiatives in the last decades dedicated not only to the search of alternative sources of chemicals and polymers, but also to suppliers of energy, both from vegetal biomass. The depolymerization of sisal cellulose may occur via acid or enzymatic hydrolysis, resulting in the fermentable sugars used in the production of the so-called cellulosic ethanol and also at the intermediate steps of the process, in micro and nanoparticles that may act as reinforcement in polymeric matrices, including those derived from cellulose. The study here reported is related to the analysis of the unreacted cellulosic material and to the liquor containing mainly glucose, from acid and enzymatic hydrolysis of sisal pulp formed by cellulose and hemicellulose. An important characteristic that involves the acid hydrolysis of biomass is the possibility of utilization of different acids, since only a source of protons in the media is required for the reaction to occur, in principle. In this context, a series of reactions of acid hydrolysis of sisal pulp was carried out under varying concentrations of sulfuric acid, from 0,9 to 4,6 molL-1, at 100°C as a first step. In a second step, the acid catalyst was replaced by oxalic acid, and the reaction lengths were bigger than those considered for sulfuric acid due to the lower value of pKa of oxalic acid. The reactions of enzymatic hydrolysis were carried out with a commercial enzymatic complex (Accellerase 1500 - Genencor), and two different pretreatments, both aiming at the elimination of hemicelluloses, were essayed as follows: mercerization and treatment with oxalic acid 0,9 molL-1. To follow the processes of acid and enzymatic hydrolysis in determined time intervals, aliquots were withdrawn from the reaction media so as to be analyzed by High Performance Liquid Chromatography (HPLC) aiming at the evaluation of the nature and content of the hydrolysis products. The unreacted cellulose suspended in the liquor was characterized by Scanning Electron Microscopy, capillary viscometry, X ray diffraction, and average size of fibers by using a fiber analyzer and light scattering. For all acid hydrolysis reactions studied, the average molar mass of the unreacted cellulose decreased up to ten times in the first minutes of reaction, and the values of crystallinity index showed that the non-crystalline regions of cellulose are firstly hydrolyzed, and the crystalline regions act as barriers to the hydrolysis. The results of HPLC showed that an increase in concentration considerably increases the yield of hydrolysis, mainly in the case of oxalic acid as a catalyst, which was not able to hydrolyze the chains of cellulose when in low concentrations (0,9 molL-1). It only eliminated the hemicellulose present in the pulp, reason why this acid was used as a pretreatment agent in enzymatic hydrolysis at this concentration. The reaction yields showed that the sulfuric acid can be up to 25% more efficient than the oxalic acid in terms of glucose production. However, the oxalic acid has the great advantage of possibly being produced from natural resources as well as being an excellent choice as a pretreatment agent for the lignocellulosic biomass to be used in hydrolysis reactions if used in the adequate concentrations. The results of enzymatic hydrolysis showed that the mercerized pulp was more efficient as raw material than the one treated with oxalic acid, as the first led to higher glucose content at the same conditions of concentration, temperature and time of reaction. The reactions of acid and enzymatic hydrolysis of lignocellulosic materials are of great importance to the production of second generation ethanol and micro and nanofibers, which may be incorporated into biocomposites. Films of chitosan matrix were prepared with the addition of cellulose fibers (untreated, mercerized and residual from the acid and enzymatic hydrolysis reactions) under various concentrations (2,5, 7,5 e 15% wt%). The films were subjected to traction analysis and its morphology was accessed by field emission scanning electron microscopy (SEM-FEG). The results showed that, in general, chitosan films (69 MPa), just like films based on chitosan-cellulose (75 MPa) presented tensile strength values that are superior or the same as similar films described in literature. Therefore, the study here reported produced promising results and is widely inserted in the current interest of utilization of materials from renewable resources instead of those from fossil resources.
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Estudo da interação de nanomateriais com modelos de membranas celulares e com células-tronco neurais / Interaction of nanomaterials with cell membrane models and with stem cellsUehara, Thiers Massami 19 September 2014 (has links)
O desenvolvimento da nanociência e nanotecnologia promoveu uma nova fronteira no estudo da matéria, permitindo que materiais já conhecidos tivessem suas propriedades redescobertas ao serem manipulados em nível molecular. Vários materiais vêm apresentando relevância na nanociência e nanotecnologia, como os nanotubos de carbono (CNTs), nanopartículas (NPs) e óxido de grafeno, uma vez que os CNTs e óxido de grafeno são dotados de propriedades mecânicas, térmicas e elétricas que os tornam apropriados para o desenvolvimento e a aplicação em dispositivos, especialmente na área biotecnológica e de sensores. Diversas áreas se beneficiam com o uso da tecnologia em nanopartículas (NPs), por exemplo: alimentícia, médica, agronegócio, cosmética, etc. Uma possível perspectiva na utilização desses nanomateriais em sistemas biológicos torna muito interessante investigar como tais materiais interagem em nível molecular com modelos de membranas celulares e com células. Esta tese tem como objetivos: i) investigar detalhadamente a interação entre nanopartículas (Fe3O4/Dextran; Fe3O4/PDAC; PDAC; Dextran) e nanotubos de carbono com modelos de membranas celulares; e ii) desenvolver nanofibras poliméricas pela técnica de electrospinning para ser utilizada com óxido de grafeno como modelos mimetizados (scaffolds) para a diferenciação de células-tronco neurais. Os filmes ultrafinos foram fabricados utilizando as técnicas de Langmuir e Langmuir-Blodgett. Esses nanomateriais foram avaliados através da técnica de Espectroscopia vibracional por Geração de Soma de Frequências. A espectroscopia SFG é sensível a interfaces. Nanofibras de Poli(ε-Caprolactone) foram fabricadas pela técnica de electrospinning. Scaffolds com óxido de grafeno/Nanofibras de Poli(ε-Caprolactone) foram desenvolvidos como suportes sólidos para a diferenciação de células-tronco neurais de rato. Óxido de grafeno em diferentes concentrações foi incorporado nas nanofibras poliméricas. Os modelos deste sistema foram investigados por imagens de Microscopia Eletrônica de Varredura. Os resultados mostraram que a carga eletrostática de cada fosfolipídio utilizado pode influenciar nas interações com os nanomateriais (nanopartículas ou nanotubos de carbono), podendo resultar em uma desestruturação no modelo de membrana celular. Scaffolds contendo nanofibras de Poli(ε-Caprolactone) com óxido de grafeno representaram um eficiente modelo mimetizado para a interação/diferenciação de células-tronco neurais de rato conforme revelado por imagens de Microscopia Eletrônica de Varredura. Estas imagens mostraram que o sistema de nanofibras de Poli(ε-Caprolactone) com 1,0 mg/mL de óxido de grafeno foram ideais para a diferenciação de oligodendrócitos em células-tronco neurais de rato. / The development of nanoscience and nanotechnology promoted a new frontier on the study of matter, allowing conventional materials to exhibit novel or improved properties. Several materials show relevance in nanoscience and nanotechnology, such as carbon nanotubes (CNTs), nanoparticles (NPs) and graphene oxide. CNTs and graphene oxide, for example, exhibit unique mechanical, thermal and electrical properties, which make them appropriate to the development and application in devices, especially in biotechnology and sensors areas. Many areas are benefited from the use of nanoparticles (NPs), such as food, medical, agrobusiness, cosmetic etc. The perspective regarding the use of nanomaterials in biological systems requires the understanding on how these materials interact at the molecular level with cell membrane models and with cells. The objectives of this thesis are: i) to investigate the interaction between nanoparticles (Fe3O4/Dextran; Fe3O4/PDAC; PDAC; Dextran) and carbon nanotubes with cell membrane models; and ii) to develop polymeric nanofibers via electrospinning technique, to be used with graphene oxide as mimic models (scaffolds) in the differentiation of neural stem cells. The cell membrane models were manufactured using Langmuir and Langmuir-Blodgett techniques. These nanomaterials were evaluated through Sum Frequency Vibrational Spectrosocopy (SFG). Poly(ε-Caprolactone) nanofibers were manufactured by electrospinning technique. Scaffolds with graphene oxide/Poly(ε-Caprolactone) were developed as solid supports for differentiation of rats neural stem cells. This biosystem was investigated via Scanning Electron Microscopy and biochemical essays. The results showed that the charge of each phospholipid influenced the interactions with the nanomaterials (nanoparticles or carbon nanotubes), in some cases, resulting in a disruption of the cell membrane model. Scaffolds with Poly(ε-Caprolactone) nanofibers obtained via electrospinning with graphene oxide represented an efficient mimic model for interaction/differentiation of neural stem cells as shown via Scanning Electron Microscopy. The images revealed that the PCL nanofibers system with 1.0 mg/mL of graphene oxide were ideal to the differentiation of oligodendrocytes in neural stem cells.
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Utilização de amido de mandioca na preparação de novos materiais termoplásticos / Utilization of cassava starch for the preparation of new termoplastic materialsTeixeira, Eliangela de Morais 07 August 2007 (has links)
Este trabalho contemplou o estudo do desenvolvimento de amidos termoplásticos (TPS) obtidos a partir da raiz de mandioca bruta e de seus derivados (amido e resíduo). A técnica de preparação deu-se por mistura física dos componentes, via estado fundido, empregando-se o plasticizante glicerol em proporções variadas. Contemplou ainda a busca de alternativas que viessem a melhorar o desempenho mecânico e a resistência à absorção de umidade dos TPS. Foi realizado um estudo inicial de caracterização dos materiais originais e constatou-se que a presença de açúcares na raiz e de fibras no resíduo é o principal diferencial com relação à composição do amido industrial. Os TPS preparados a partir de amido industrial e de raiz apresentaram fraco desempenho mecânico. Por outro lado, as fibras presentes no resíduo foram capazes de gerar TPS com melhores propriedades mecânicas. Os açúcares naturalmente presentes na raiz ocasionaram um efeito adicional de plasticização ao TPS influenciando principalmente nas propriedades de alongamento na ruptura. Os TPS preparados apresentaram comportamentos semelhantes frente à absorção de água. As estratégias empregadas na tentativa de melhorar o desempenho do TPS preparado a partir de amido de mandioca industrial foram: desenvolvimento de blendas de TPS com poli (álcool vinílico) (PVA); adição de látex de borracha natural às blendas TPS/PVA; uso de partículas minerais (alumina e carbeto de silício) aos TPS e uso de nanofibras de celulose (whiskers) como reforço aos TPS. Estas nanofibras foram extraídas a partir das fibras contidas no resíduo da industrialização do amido de mandioca. Em todos os casos foram realizados estudos da morfologia e do desempenho dos materiais resultantes. Os resultados revelaram que as blendas TPS/PVA e TPS/PVA/látex foram, em sua maioria, imiscíveis, porém compatíveis, pois o desempenho mecânico e de resistência à umidade foram aumentados. O látex, empregado em conjunto com o PVA, gerou materiais com módulo elástico cerca de 1330% maior que a combinação TPS/látex, além de reduzir a absorção de água das blendas TPS/PVA em 12%. A alumina (Al2O3) promoveu um efeito de plasticização no TPS ocorrendo um aumento de 68% no alongamento. Em contrapartida, houve uma redução de 70% no módulo elástico e de 40% na tensão de tração na ruptura. O carbeto de silício (SiC) mostrou-se efetivo no aumento do módulo elástico (aumento de 230%). O efeito de reforço acarretado pelos ´whiskers´ foi limitado devido à presença de açúcares decorrentes da hidrólise ácida do amido residual contido no resíduo. Os testes de resistência à tração não foram sensíveis para a completa determinação das propriedades mecânicas. Entretanto, os resultados de análise térmico-dinâmico-mecânica revelaram que houve um aumento de 26% no módulo de armazenamento. A principal contribuição do uso destas nanofibras deu-se na redução de absorção de água (34% em relação ao TPS sem ´whiskers´). Como um todo, os resultados obtidos nesta tese revelaram a possibilidade de obtenção de TPS a partir da mandioca e de seus derivados e que as estratégias adotadas para melhorar o desempenho final dos TPS foram satisfatórias. / In this work it was studied the development of thermoplastic starches (TPS) prepared from raw cassava root and its derivatives, starch and bagasse (residue). The TPS were prepared by melt-processing employing glycerol as plasticizer in distinct proportions. It was searched for alternatives that could improve both, the mechanical performance and resistance to water of the TPS. It was made a previous characterization of the original materials. It was verified that the presence of sugars in the cassava root and of fibres in the bagasse is the main distinction in relation to the composition of industrial starch. The TPS from industrial starch and cassava root presented the poorer mechanical performance. On the other hand, the fibres in the bagasse allowed the obtainment of a more mechanical resistant TPS in relation to the other TPS. The presence of natural sugars in the cassava root promoted an additional effect on the plasticization of TPS, influencing mainly the elongation properties. The prepared TPS presented similar behaviors in relation to water absorption. The strategies adopted to improve the performance of TPS prepared from industrial starch were: the development of TPS blends with polyvinyl alcohol (PVA); addition of latex of natural rubber to TPS/PVA blends TPS/PVA; the use of mineral particles (alumina and silicon carbide) to the TPS and also, utilization of cellulose nanofibres (whiskers), as reinforcement to the TPS. These whiskers were extracted from the fibres contained in the cassava bagasse. For all the cases the morphology and final performance of the resulting materials were investigated. The results revealed that TPS/PVA and TPS/PVA/latex blends were in a greater number immiscible, although, compatibles since, the mechanical performance and water resistance were increased. The latex, employed together PVA, promoted a 1330% increase in the elastic modulus compared to TPS/latex. Also, the water absorption of TPS/PVA blends was reduced in 12%. The alumina (Al2O3) promoted a plasticizing effect in the TPS with an increase of 68% in elongation. On the other hand, the elastic modulus and tensile strength were reduced in 70% and 40%, respectively. The silicon carbide (SiC) was effective to increase the elastic modulus (increase of 230%). The reinforcement effect of the whiskers was limited due to the presence of sugars resultants of the acid hydrolysis of residual starch present in the bagasse. The tensile tests were not sensitive to determine the mechanical properties. However, from dynamicmechanical tests it was verified an increase of 26% in the storage modulus. The main contribution of the use of nanofibers was on the reduction of water absorption in 34% compared to TPS without nanofibers. As a whole, the results obtained in this work revealed the possibility of preparation of TPS from cassava root and its derivatives and that the strategies adopted to improve the final performance of the TPS ware successful.
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Development of nano-graphene cementitious composites (NGCC)Ilyas, Muhammad January 2016 (has links)
Ordinary Portland cement (OPC) is the main constituent of concrete works as a principal binder for aggregates and intrinsically transmits the brittleness into concrete through the formation of hydration crystals in the cement microstructure. A number of nano cementitious composites were developed in recent years to offset the brittleness with newly discovered nanomaterials and the most prevalent among those is the graphene oxide (GO). The main objective of this PhD research work is to develop nano graphene cementitious composites (NGCC) using low cost, two dimensional (2D) graphene nanoplatelets (GNPs) and one dimensional (1D) graphited carbon nanofibres (GCNFs) with unique conical surface morphology. The GNPs were sourced synthesised in an environmental friendly way via plasma exfoliation whereas, GCNFs were manufactured through catalytic vapour grown method. The project further investigated the effect of these nanomaterials in regulating the distinctive microstructure of cement matrix leading to enhance its mechanical properties. Three different types of high-performance NGCC namely NGCC-Dot, NGCC-Fnt and NGCC-CNF, are developed by activating pristine GNPs (G-Dot), functionalised GNPs (G-Fnt) and graphited nanofibers (G-CNFs) into the cement matrix respectively. It is found through various characterization and experimental techniques that both GNPs and GCNFs regulated the cement microstructure and influenced the mechanical properties of NGCC uniquely. A remarkable increase in the flexural and the tensile strength of newly developed NGCC has been achieved and that could be attributed to the formation of distinctive microstructure regulated by catalytic activation of these nanomaterials. The shape (1D, 2D) and unique morphology of these nanomaterials played a vital role in the mechanism of crystal formation to regulate the cement microstructure. Based on the observations of test results and comprehensive characterization, the possible mechanisms of crystal formation and development of distinctive microstructure of NGCC has been established which has then proceeded to the development of a physical model for NGCC development.
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Supramolecular engineering of optoelectronic sensing devices / Ingénierie supramoléculaire de capteurs optoélectroniquesSquillaci, Marco 26 September 2017 (has links)
Cette thèse explore l’utilisation des principes de la chimie supramoléculaire afin de fabriquer des dispositifs senseurs de gaz novateurs et à haute performance, avec une lecture (opto)-électronique. Parmi les différentes sections, divers échafaudages tels que des réseaux hybrides bi- et tridimensionnels de particules d’or et des nanofibres supramoléculaires sont utilisés comme matériaux actifs pour la détection quantitative de l’humidité. Au sein de la dernière section, des couches 2D d’oxyde de graphène sont fabriquées par exposition à un laser IR, puis comme validation de principe, exploitées comme matériau actif pour la détection d’ozone à une concentration ppm. Chacun des échafauds présentés est basé sur un mécanisme de transduction différent, mais dans tous les cas, les interactions entre récepteurs et analytes sont basés sur des liaisons dynamiques non covalentes. / This thesis explores the use of supramolecular chemistry principles to fabricate novel and high performances gas sensing devices, featuring (opto)-electronic readouts. Within the different sections, diverse scaffolds such as 2D and 3D hybrid networks of gold nanoparticles and 1D supramolecular nanofibers are exploited as active materials for the quantitative detection of environmental humidity. In the last section, 2D layers of reduced graphene oxide are fabricated by IR laser exposure and, as a proof-of-concept application, they are exploited as active materials for the detection of ozone in ppm concentration. Each of the presented scaffolds rely on a different transduction mechanism but, in all the cases, the interactions between the receptors and the analytes are based on dynamic non-covalent bonds.
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Filage par voie électrostatique de polyamide-imide : applications de non-tissés nanofilamentaires à la protection contre la chaleur et les flammes / Electrospinning of meta-aramid polymer solutions (polyamide-imide) : nanofibrous non-woven applications for protection against heat and flameOertel, Aurélie 03 May 2017 (has links)
Le filage par voie électrostatique est une technique utilisée pour la production de fibres de diamètres extrêmement petits, de l’ordre de quelques centaines de nanomètres, possédant, sous forme de non-tissés, une grande surface spécifique. Les matériaux non-tissés composés de nanofibres sont de plus en plus utilisés pour de multiples applications, notamment dans le domaine de l’ingénierie tissulaire, pour les textiles de protection, la filtration, le biomédical, l’électronique et l’ingénierie environnementale. Le contrôle des paramètres lors du filage par voie électrostatique est primordial pour obtenir des nanofibres dont les propriétés morphologiques seront optimisées (diamètres des nanofilaments obtenus fins et contrôlés ; qualité de filage acceptable). Le but de ces travaux de thèse est d’établir la faisabilité d’électrofilage des deux solutions de polyamide-imide (le KMP et le KMT) fournies par la société Kermel. Puis, une fois la faisabilité de filage établie, de déterminer plus précisément les paramètres influençant le procédé, afin d’optimiser le procédé de filage et obtenir des nanofilaments à partir des deux solutions de polymères, à l’échelle laboratoire et sur un outil de production à l’échelle semi-industrielle. Cette thèse a fait l’objet d’une collaboration entre l'entreprise alsacienne Kermel, fabricant de fibres techniques résistantes à la chaleur et aux flammes, situé à Colmar et le Laboratoire de Physique et Mécanique Textiles (LPMT) à Mulhouse. Les nanofibres ont été définies ainsi que différentes techniques de filage permettant leur obtention. Les fournisseurs d’équipement ont été identifiés dans un souci de production semi-industrielle à terme. La technique de filage par voie électrostatique (avec ou sans aiguilles) est finalement retenue, car il s’agit de l’outil de prototypage et de compétences disponibles au laboratoire LPMT et dont le passage à l’échelle industrielle est envisageable. La technique des plans d’expériences a été utilisée afin d’optimiser le nombre d’essais de filage nécessaires à l‘étude des diamètres de nanofilaments obtenus. Les différents paramètres liés aux propriétés de la solution de polymère (température, viscosité, concentration) ont été étudiés et les aspects rhéologiques affichés. Une interprétation physico-chimique des comportements observés pour les différentes solutions de polymère est faite. Elle nous permet de conclure que le meilleur régime pour obtenir des nanofibres est le régime concentré, puisqu’il s’agit du régime où la densité de macromolécules est la plus forte. La faisabilité de l’électrofilage du polyamide-imide sur l’équipement à échelle laboratoire du LPMT a été établie. La température, l’humidité et la concentration sont étudiées. Les différentes plages d’optimisation d’électrofilage du polymère considéré ont été établies et il est possible d’envisager le passage à l’échelle semi-industrielle. Le paramètre le plus influent sur les diamètres de fibres obtenus est l’humidité relative, ce qui n’avait jusqu’à présent jamais été mis en avant dans la littérature. La même démarche d’optimisation a été réalisée sur l’équipement semi-industriel. Des applications « produit » ont pu être envisagées. Notamment une application liée à la filtration où une étude de perméabilité à l’air a été réalisée. Cette étude a permis de conclure que l’ajout d’une couche de nanofibres sur un support en tissu permet de diminuer d’1/3 à 2/3 les résultats de perméabilité à l’air. Une corrélation est faite entre les diamètres de nanofibres et les résultats de perméabilité à l’air obtenus, qui est cohérente avec le comportement attendu. Enfin des tests « qualité » ont été réalisés sur des échantillons produits : le taux de solvant résiduel obtenu dans les conditions de filage optimisées est inférieur à 8% ; et des tests de résistance à l’abrasion menés sur des non-tissés recouverts de nanofibres ont donné des résultats encourageant [...] / Electrospinning process has been widely used over the past decades for manufacturing nanofibers. The control of the electrospinning parameters is crucial to obtain nanofibers (nonwoven mats) with optimized morphological properties. The aim of this PhD work is to precisely define the electrospinnability of two meta-aramid solutions through wire-based electrospinning setup processing. Although the viscosity of polymer solution as an influent parameter for electrospinning has been widely investigated, only a few studies have yet made a connection between rheological behavior of polymer and electrospinnability. In our PhD work, rheological analyzes on three meta-aramid solutions have been conducted to confirm its electrospinnability and predict the morphological behavior of resultant nanofibers. A couple polymer/solvent of meta-aramid polymer (polyamide-imide) in a polar aprotic solvent (1,3 dimethyl-2-imidazolidinone) at 60 Pa.s in working viscosity is provided by an industrial partner (KERMEL Company). It has been highlighted through rheological study that 60 Pa.s is the best polymer viscosity to obtain good macromolecular conformation of the polyamide-imide chains while electrospinning and sufficient viscoelastic properties. Experiments have been conducted following a design of experiment to study the influence of several process and ambient parameters. Individual effects and/or combined interactions on obtained fiber diameter and general morphology have been investigated. The obtained nanofibers are expected to have thin diameters with high homogeneity of the products, which means low levels of beads, residual solvent or non-fibrous area and a narrow fiber diameter distribution, in order to validate the industrial requirements. A wide range of process parameters are available at industrial-scale with the NS® technology. The five studied process parameters are: applied voltage, relative humidity, temperature, distance between spinning electrode wire and substrate material, and airflow going through the spinning chamber. Each parameter was varied at three levels. Significant effects of parameters have been observed. The obtained results have allowed us to determine the influential factors (humidity and temperature) and reduce the domain study. Moreover, an estimation of the capacity of production for the NS500 has been calculated for the tested meta-aramid solution. Several applications have been investigated. A nanofibrous coating on 50KMP/50VFR woven media has been produced and permeability air tests have been conducted. A decrease of 1/3 to 2/3 of air permeability results has been obtained. A correlation is drawn between mean diameters of nanofibers and air permeability values, which is coherent with the expected behavior. Quality tests have been conducted through thermogravimetric analyses and proton nuclear magnetic resonance. The residual solvent rate obtained in the optimized conditions of spinning is less than 8 %. Abrasion resistance tests have been conducted on KMP non-woven media coated with nanofibrous layer. The use of the bi-layer structure does not lead to the formation of breathable particles.
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Optimisation de la structure textile des prothèses vasculaires pour un développement en monocouche des cellules endotheliales / Vascular textile prostheses optimization for an endothelial cells monolayer devlopmentFrançois, Sébastien 07 December 2009 (has links)
Les prothèses vasculaires textiles en polyéthylène téréphtalate (PET) présentent souvent des occlusions après implantation pour les petits diamètres (6-8mm) car la surface des prothèses est peu hémocompatible. Or, l'hémocompatibilité des prothèses serait largement améliorée si ces dernières se recouvraient d'une couche de cellules endothéliales qui tapissent naturellement les vaisseaux sanguins. Ce projet vise à mettre en évidence que les textiles bruts ne sont pas un support viable pour le développement de ces cellules endothéliales, puis propose de remplacer les matrices protéiniques par un recouvrement synthétique. Pour ce faire, de l'acide poly-L-lactique (PLA) solubilisé a été filé sous forme de nanofibres déposées sur la surface luminale de la prothèse. L'étirage par jet d'air a été caractérisé selon un modèle plan, puis adapté à la fon11e tubulaire des prothèses. Les nanofibres ont été évaluées sur le plan de la cytocompatibilité, de l'adhérence et de la prolifération avec un modèle de cellules endothéliales animales. Ce travail vise aussi à optimiser l'adhérence de ces fibres sur le PET par l'emploi d'une technique de modification de surface par plasma. Les résultats montrent qu'il est possible de produire des nanofibres de PLA et de contrôler leur diamètre, et de sceller la paroi de la prothèse textile. Enfin, les cellules endothéliales prolifèrent en monocouche sur des prothèses recouve1tes de nanofibres. Il est possible d'optimiser l'adhérence des nanofibres sur le PET avec un traitement par plasma. En conclusion nous avons proposé une alternative à l'enduction traditionnelle des prothèses permettant la prolifération en monocouche des cellules endothéliales. / Textile vascular prostheses show poor patency rate for smaller diameter grafts (6-8mm). Mainly due to thrombosis or hyperplasia, graft failures can be explained by meagre hemocompatibility. Lack of neoendothelialization of the inner wall of the graft can be one reason explaining this poor hemocompatibility, This project aimed to prove that bare textiles are not a good support to stand endothelial cells' proliferation. Poly(L-latic) acid was therefore chosen to replace protein coating by being formed as a nanofibres mesh on the PET textile prostheses luminal surface. Air jet spinning process was first evaluated in a basic planar model to determined optimal parameters for nanofibres production. Endothelial cells compatibility, adhesion and proliferation were tested. Then air jet spinning was dedicated to tubular shape of textile vascular prostheses. Nanofibres mesh were analysed for chemical and physical properties, and covered graft were tested for water permeability. Lastly, atmospheric pressure plasma treatment was performed to optimize PLLA nanofibres adhesion on PET. Results showed that nanofibre diameters were controlled by polymer concentration. Nanofibre cristallinities depend of spinning parameters. Air jet spinning allows quick covering of textile surfaces with a dense net of nanofibre scelling the inner wall of the prosthesis, even in tubular samples. Moreover, endothelial ceIls show monolayer proliferation on these nanofibres. Finally, Polylactic acid adhesion on PET was optimized with atmospheric pressure plasma. In conclusion, we bring a new solution to cover inner wall of prostheses, allowing a monolayer proliferation of endothelial cells.
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Povrchová funkcionalizace materiálů s využitím plazmových technologií / Surface functionalization of the materials by plasma technologiesTROUP, František January 2014 (has links)
This thesis deals with the plasma functionalization of nanofiber materials for biomedical applications. Nanofibers of SiO2 and PCL was functionalized using a microwave plasma in order to establish amine functional groups. The work includes theoretical assumptions selection of these materials, their properties and current use with emphasis on biomedical applications. The paper also presents the theoretical foundations of plasma technology, their principles and practical applications. The experimental part of the work includes the optimization of process parameters for each nanofiber materials, review hydrophilisation surface and material degradation through SEM and private functionalization. In conclusion outlines proposals for further action beyond the experiments of this work.
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